Apparatus and method to recover and dispense potable water

ABSTRACT

An apparatus and system to produce purified drinking water from humid air is provided. The apparatus includes an air purification device such as a HEPA filter to remove air-borne particulate and biological containments. A method to provide purified drinking water from humid air using a stand along apparatus is provided. The apparatus can also dehumidify, improve air-quality and provide air-conditioning.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional patent application Ser. No. 61/345,682 filed May 18, 2010 under 35 USC §119(e) (hereby specifically incorporated by reference).

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

None.

REFERENCE TO SEQUENCE LISTING, A TABLE OR A COMPUTER PROGRAM LISTING, COMPACT DISC APPENDIX

None.

FIELD OF THE INVENTION

This invention primarily relates to an apparatus to recover and dispense potable water and secondarily to dehumidify, improve air-quality and provide air-conditioning in certain embodiments.

BACKGROUND OF INVENTION

In a refrigeration cycle, a refrigerant changes vapor to liquid and give up heat in the condenser coil (“hot coil”). Refrigerant changes from liquid to vapor and removes heat from the system with an evaporator coil (“cool coil). A refrigeration system is powered by a compressor. Most central air conditioners are connected to a structure's forced-air distribution system. Thus, the same motor, blower, and ductwork used for heating are used to distribute cool air from the air conditioning system. When a central air conditioner is operating, hot air inside the structure flows to the furnace through the return-air duct. The hot air is moved by the blower across the cooled evaporator coil in the plenum and is then delivered through ducts to cool the structure. The coil used in air-conditioning apparatus, such as a furnace, air handling units, heat pumps and package air conditioners, extracts moisture from the air which flows across the coil. The moisture extracted creates a condensate on the exterior of the evaporator coil which drips into a drain pan. A condensate drain pan catches condensate that forms on the coil or return tubing and the condensate is delivered via condensate drain conduit away from the apparatus, as shown for example in U.S. Pat. No. 7,430,877.

In many areas of the world, air and water quality problems are common. These problems include lack of clean drinking water, air contaminated with particulate and poor indoor air quality because of high humidity. Portable water production units have been developed to condense water out of humid air. One example, of a device to produce potable water, is disclosed by Reidy, U.S. Pat. No. 5,106,512 (column 17). However, potable water production units that have been developed to condense water out of humid air produce an inadequate amount of water over a period of time and it is not worth the energy cost to produce such a small amounts of water with the prior art devices.

BRIEF SUMMARY OF THE INVENTION

An apparatus to purify water is provided that has features that allow the production of a sufficient amount of water to make the investment in energy to operate the device a viable option in developing countries for making potable water and improving living conditions. In particular, an apparatus configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein the device includes an evaporation surface having corrugated shaped fins of between 5-8 fins per cm coupled with a fan to facilitate movement of air across the evaporator device, can efficiently condense water. In addition to the aspects of the invention that increase the quantity of water produced over time, the quality of the water, can also be improved using an air purification unit that substantially covers the air inlet for ambient air of the apparatus. In the preferred embodiment, the air purification unit, is a HEPA filter from between 2.5 to 11 cm in thickness. Additionally, in one embodiment, at least one water purification unit is positioned to purify the condensed water. In another embodiment, the apparatus additionally produces cool air. This embodiment additionally includes: an air-conditioning coil and a second fan positioned to expel cold air from the outlet ports of the apparatus.

More specifically this apparatus include: a housing including an inlet to intake ambient air, an air purification unit substantially covering said inlet, an evaporator device configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein the device includes an evaporation surface having corrugated shaped fins of between 5-8 fins per cm; a fan to facilitate movement of air across the evaporator device to condense water; a reservoir to hold condensed water; and at least one water purification unit positioned to purify the condensed water; and a dispensing device to dispense potable water.

The apparatus is used to make potable water by operating the fan at one speed to facilitate the extraction of water from ambient air and at a second speed to expel cold air from a plurality of outlet ports in the housing. This method produces about 26.5 liters of potable water in 18 hours of operation.

In another embodiment, this invention provides a system to provide air-conditioning to a structure and recover and dispense water. This system is made of: at least one housing including an inlet to intake ambient air, an air purification unit substantially covering said inlet, an evaporator device configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein the device includes an evaporation surface having corrugated shaped fins of between 5-8 fins per cm, wherein the evaporator device is in fluid communication with a condensing coil; a fan to facilitate movement of air across said evaporator device to condense water; at least one reservoir to hold condensed water; and at least one water purification unit positioned to purify the condensed water; and a dispensing device to dispense potable water, and a fan positioned to expel cold air from outlet ports, wherein the at least one housing is attached to a dwelling.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

Other objects, features and advantages will occur to those skilled in the art from the following description of the preferred embodiments, and the accompanying drawings, in which:

FIG. 1 shows a schematic side elevational view of one embodiment of the apparatus.

FIG. 2 shows a schematic front elevational view of one embodiment of an apparatus.

FIG. 3 shows a schematic view of one embodiment of an apparatus.

FIG. 4 shows a schematic view of one embodiment of an apparatus.

FIG. 5 shows a schematic view of one embodiment of an apparatus.

FIG. 6 shows a schematic a view of one embodiment of an apparatus.

FIG. 7 shows a schematic view of the fixed embodiment of an apparatus.

FIG. 8 shows a schematic view of a portion of the fixed embodiment of the apparatus.

FIG. 9 shows a schematic view of a portion of the fixed embodiment of the apparatus.

FIG. 10 shows a schematic view of a portion of the fixed embodiment of the apparatus.

FIG. 11 shows a schematic view of one embodiment of an apparatus.

FIG. 12A shows a schematic view of one embodiment of an apparatus.

FIG. 12B shows a schematic view of one embodiment of an apparatus.

FIG. 12C shows a schematic view of one embodiment of an apparatus.

FIG. 13 shows a schematic view of one embodiment of an apparatus.

FIG. 14 shows a schematic the electrical configuration of the apparatus.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made to the exemplary embodiments illustrated in the drawings, and specific language will be used herein to describe the same. Now referring to FIGS. 1-3, a portable apparatus 1 to produce drinking water is shown. Apparatus 1 is made of a housing 2 and alternatively includes wheels 3 to move the apparatus 1. The housing 2 has at least one face 4 including an inlet to intake ambient air 5, such as, a plurality of opening, such as, holes, louvers or perforations 5. The air inlet 5 allows ambient air to enter the apparatus 1. The term ambient air means air from inside or outside of a structure, such as a dwelling.

The ambient air contacts an air purification unit, such as, a filter 6. This air purification unit 6, in the preferred embodiment, is an in-line high efficiency particulate air “HEPA” filter that substantially covers the air-inlet 5. Filter 6 is attached to the housing 2 using brackets (not shown) to provide a secure attachment and can be off-set from the housing 2 by a space. In the preferred embodiment, the space is about 2.5 cm. The brackets are configured to seal the space around filter 6 to prevent air from entering the apparatus 1 that has not passed through filter 6. In an alternative embodiment the filter is electrostatic.

In one embodiment, filter 6 is placed inside of the housing 2. The filter 6, in the preferred embodiment, is a HEPA filter 6 that is between about 2.5 to 11 centimeters in thickness. The filter 6 is sized to remove air-borne particulate and biological hazards, such as bacteria and/or viruses. In another embodiment the filter is electrostatic. In an alternative embodiment the air purification unit can include in-line air purifying device 47 using ozone and ultraviolet light of an in-line air-purification device 47 is used without a HEPA filter, a dust filter (not shown) should be used to reduce particulate.

Inside the housing 2, moist ambient air is drawn over an evaporator device 10 with an evaporating surface, by a fan 11 positioned to facilitate the movement of air across the evaporation surface. Since the saturation vapor pressure of water decreases with decreasing temperature, the water in the air condenses, and drips into a reservoir 20. In the preferred embodiment, the evaporator device 10 includes of a series of tubes and substantially perpendicular fins 7. The fins 7 are selected to facilitate condensation of moisture from the air and in the preferred embodiment are corrugated and are configured as 5-8 fins per centimeter, and most preferably 6-7 fins per centimeter. The evaporator device 10 can be made of stainless steel or food-grade composite plastic or alternately coated with a food-grade coating. The water flows from the evaporator device 10 to storage reservoir 20 via tube 21.

The storage reservoir 20 can be any container or storage mechanism known in the art. Preferably, as depicted in FIG. 1, a storage reservoir 20. Is configures to hold condensed water. Storage reservoir 20 is made of any material which exhibits the necessary structural strength without contaminating the stored water, such as stainless steel or food-grade composite plastic. Reservoir 20 should be large enough to have sufficient capacity to store the desired amount of condensed water, yet be small enough to fit within the space available in housing 2. The capacity of the storage means depends on the size of housing 2. Generally; the capacity can range from about 3.8 to about 38 liters, and preferably is about 26.5 liters. The storage reservoir 20 can be provided with any suitable sensor 16 and accompanying shut-off device as known in the art to control the level of the water in the storage means and prevent overflow. See, for example, U.S. Pat. Nos. 5,149,446 (column 4) and 5,301,516 (column 5), the disclosures of which are incorporated herein by reference. The storage reservoir 20 can also be provided with a secondary or back-up reservoir, (not shown) either internal or external to the housing 2 to collect water if no additional water is required.

The condensed water in the storage reservoir 20 is usually not suitable for drinking and other sanitary uses. Thus, the condensed water must be purified and/or cleaned prior to being dispensed. The purification process is achieved using at least one water purification unit. Purification processes, as known in the art, can be employed in the present invention to clean the water. For example, U.S. Pat. Nos. 4,204,956 (column 5), 5,227,053 (column 15), 5,669,221 (column 15), and 5,845,504 (column 25), 6,182,453 (column 46) & 7,272,947 are (column 35) hereby incorporated by reference disclose such elements.

In the preferred embodiment a two step purification process is employed. In the first step an ozonator 26 provides ozone to storage reservoir 20 via line 27. The ozone is delivered substantially near the side of the storage reservoir 20 to facilitate mixing. In the second stage, line 29 feeds the condensed water through a purification unit 28, the purification unit 28 can include a variety of methods to purify the water including: UVC, ultrasound, ozone, and/or heat.

The water is manually dispensed on an on-demand basis when a control circuit is activated, the water is pumped, via pump 30 from storage reservoir 20 through the purification unit 28 at least once, and then out dispenser 40. The apparatus 1 unit can produce on average 1 gallon a day at the @70% humidity at 85 degree F. using approximately 0.019 KW/Gal.

In the alternative embodiment, a heating coil 41 can be positioned to heat the water for delivery. Alternatively, line 29 can be wrapped with a tube containing chilled water from suction line (not shown), high-pressure line (not shown) of the operating compressor 46 to cool the dispensed water or in the alternative a line (not shown) can be run close to the evaporating coil 10 to cool the water.

A plurality of outlet ports for air 50 are provided in one face of the housing 2. To reduce particulate in the interior of the housing 2, the outlet ports 50 in one face of the housing 2 can include shutters 52 that open to expel air, but close when air is not exiting the apparatus 1, to reduce the amount of particulate in the apparatus 1.

Now referring to FIGS. 4-6, an apparatus 101 that can provide air-conditioning and purified water is shown. This apparatus 101 has a housing 102. In this embodiment, an air-conditioning coil 104, and air-conditioning fan 115 are shown in the apparatus 101. The hot air from the air-conditioning coil 104 is exhausted from port 150. Cool air exits the apparatus 101 via vent 180 when fan 185 is activated. A compressor 146 powers the movement of refrigerant thorough the coils, wherein an evaporator coil of the evaporator device 110 is in fluid communication with a condensing coil 104.

The housing 102 has includes air inlets to intake ambient air 105, such as, a plurality of opening, such as, holes, louvers or perforation. The air inlets 105 allow ambient air to enter the apparatus 101. Inside the housing 102, moist ambient air is drawn over an evaporator device 110, such as evaporating surface with an evaporator fan 111. The ambient air contacts an air purification unit 106, such as an in-line high efficiency particulate air “HEPA” filter that covers the plurality of opening 105. Filter 106 is attached to the housing brackets (not shown) to provide a secure attachment and can be off-set from the housing 102 by a space. In the preferred embodiment, the space is about 2.5 cm. The brackets are configured to seal the space around filter 106 to prevent air from entering the apparatus 101 that has not passed through filter 106. In one embodiment, filter 106 is placed inside of the housing 102. The filter 106 is sized to remove air-borne particulate and biological hazards, such as bacteria and/or viruses. In an alternative embodiment the filter is electrostatic.

In the preferred embodiment, the evaporator device 110 is made of a series of tubes and substantially perpendicular fins 107. The fins 107 are selected to facilitate condensation of moisture from the air and in the preferred embodiment are corrugated and are configured as 5-8 fins per centimeter, and most preferably 6-7 fins per centimeter. The evaporator can be made of stainless steel or food-grade composite plastic or alternately coated with a food-grade coating.

A drain pan 112 is positioned to facilitate the removal of water. The drain pan 112 is preferably made of stainless steel or food-grade composite plastic. The water flows from the drain pan 112 to storage reservoir 120. In the preferred embodiment, tube 121 connects the drain pan 112 to storage reservoir 120. The water in the storage reservoir 120 is purified. The preferred embodiment uses a two step purification process. In the first step, an ozonator 126 provides ozone to storage reservoir 120 via line 127. The ozone is delivered ozone via a dispenser 186 substantially near a side of the storage reservoir 120 to facilitate mixing. In the preferred embodiment, a platform 123 is included in the storage reservoir 120 to facilitate mixing.

In the second stage, line 129 feeds the condensed water through a purification unit 128, the purification unit can include a variety of methods to purify the water including: UVC, ultrasound, ozone, and/or heat. In this embodiment a purification unit 128 includes: string-wound sedimentation filter 174 carbon block filer 176 and a second carbon block filter 178. Additionally, the purification unit can include a UVC element 179. The purification unit 128 can include an active carbon filter to remove organic chemicals, and alternatively a dust filter.

The water purified water can be re-circulated to reservoir 120 or in an alternative embodiment fed directly to in line UVC unit 179 via line 181. Line 182 provides water from reservoir 120 to UVC element 179. The water is manually dispensed on an on-demand basis when a control circuit is activated, the water is pumped, via pump 130, through storage reservoir 120 through the purification unit 128 at least once, and then out dispenser 145. The apparatus 101 can produce about 26.5 liters of water in 18 hours of operation at 70% humidity at 85 degrees F.

Now referring to FIGS. 7-8, an apparatus 201 to produce drinking water and provide air conditioning is shown. Apparatus 201 is made of a housing 202. The housing 202 has at least one face 204 including an inlet to intake ambient air 205, such as, a plurality of opening, such as, holes, louvers or perforations. The air inlet 205 allows ambient air to enter the apparatus 201. The ambient air contacts an air purification unit 206, such as an in-line high efficiency particulate air “HEPA” filter that covers the plurality of opening 205. Filter 206 is attached to the housing brackets (not shown) to provide a secure attachment and can be off-set from the housing 202 by a space. In the preferred embodiment, the space is about 2.5 cm. The brackets are configured to seal the space around filter 206 to prevent air from entering the apparatus 201 that has not passed through filter 206. In one embodiment, filter 206 is placed inside of the housing 202. The filter 206 is sized to remove air-borne particulate and biological hazards, such as bacteria and/or viruses. In an alternative embodiment the air purification unit 206 can include an in-line air purifying device 247. In an alternative embodiment the filter is electrostatic.

Inside the housing 202, moist ambient air is drawn over an evaporator device 210, with an evaporating surface, with a fan 211, positioned to facilitate movement of air across the evaporating surface. Fan 211 can operate at low, medium and high speeds. High speed is used in the air-conditioning mode. Since the saturation vapor pressure of water decreases with decreasing temperature, the water in the air condenses, and drips into a drain pan 212. The cool air can be used to cool down the warm refrigeration coil 213. Solenoid 257 allows refrigerant flow to evaporator 210 and solenoid 258 allows flow to the condenser 213. When the apparatus 201 is in the “on-mode” and a sensor such as a thermostat 259 reaches a high set point solenoid 257 closes and solenoid 258 opens and allows refrigerant to flow to the condenser 213. When thermostat 259 reaches a low set point solenoid 257 opens and solenoid 258 closes so that refrigerant flows to the evaporator 210. When the machine is in the “off mode,” if the thermostat 259 reaches the high set point, solenoid 257 closes and solenoid 258 opens to allow refrigerant to the condenser 213. If the compressor 246 is on and the fan 211 is on and the thermostat 259 reaches a low set point then solenoid 257 closes and solenoid 258 closes to turn the compressor 246 off and the fan 211 off.

In one embodiment, a plurality of outlet ports for air 250 is provided in one face of the housing 202. To reduce particulate in the interior of the housing 202, the outlet ports 250 in one face of the housing 202 shutters 252 substantially cover the outlet ports that open to expel air, but close when air is not exiting the apparatus 201. Additionally, a fan 211 is positioned to expel cold air from the plurality of outlet ports 250.

In this embodiment the condenser coils of the condenser 213 range from 1.48 to 7.59 face area in sq. m. depending on the size of the apparatus 201. The fins per centimeter range from 1 to 6. In the preferred embodiment, the condenser coil 213 is made of aluminum fins and copper tubing. A compressor 246 powers the movement of refrigerant thorough the coils. Various types of compressors can be used including reciprocating hermitic and scroll.

In the preferred embodiment, the evaporator device 210 is made of a series of tubes and substantially perpendicular fins 207. The fins 207 are selected to facilitate condensation of moisture from the air and in the preferred embodiment are corrugated and are configured as 5-8 fins per cm, and most preferably 6-7 fins per centimeter. The face area of the evaporator device 210 included coil ranging from 7 to 35.6 sq. ft. The evaporator device 210 can be made of stainless steel or food-grade composite plastic or alternately coated with a food-grade coating.

In an alternative embodiment, the fins 207 are periodically agitated by an agitation device 214 to facilitate the removal of water. This can be accomplished by mechanical device, such as. a plunger or a shaker or by an acoustic vibration. The frequency of the vibration is related to the amount of water required. The agitation device 214 can be triggered by a relative humidly sensor, a temperature sensor 259 or timed to occur at fixed intervals.

The water flows from the drain pan 212 to storage reservoir 220. In one embodiment, the drain pan positioned in at least a 5 degree angle from the evaporator device to facilitate the removal of moisture. In the preferred embodiment, tube 221 connects the drain pan 212 to storage reservoir 220. The tube 221 can have a “U” shape to form a water seal to prevent ingress of tramp air into reservoir 220. In an alternative embodiment, a pre-filter 222 is in fluid communication with the drain pan 212. The pre-filter 222 can include a particulate screen for removing particles larger than a predetermined size from water passing through the pre-filter 222.

The storage reservoir 220 can be provided with any suitable sensor 216 and accompanying shut-off device as known in the art to control the level of the water in the storage means and prevent overflow. See, for example, U.S. Pat. Nos. 5,149,446 (column 4) and 5,301,516 (column 5), the disclosures of which are incorporated herein by reference. The storage reservoir 220 can also be provided with a secondary or back-up reservoir, (not shown) either internal or external to the housing 202 to collect water if no additional water is required. The apparatus 201 can produce about 26.5 liters of water in 18 hours of operation.

The condensed water in the storage reservoir 220 is usually not suitable for drinking and other sanitary uses. Thus, the condensed water must be purified and/or cleaned prior to being dispensed as previously described. In the preferred embodiment a two step purification process is employed. In the first step an ozonator 226 provides ozone to storage reservoir 220 via line 224. The ozone is delivered via a nozzle 286 substantially near the side of the storage reservoir 220 to facilitate mixing. In the preferred embodiment, a platform 223 is included in the storage reservoir 220 to facilitate mixing. An artificial one way air valve 248 allows outside air to enter the storage reservoir 220. Water can be recycled thorough reservoir 220 via line 227 via pump (not shown). A level sensor 216 is reservoir 220 shows level of water. When water reaches this level, water is removed from the reservoir 220 through conduit 239 through at least one water purification element 228.

Now referring to FIG. 8, a second larger reservoir 230 is provided that can be fluidly connected to the storage reservoir 220. A pump 218 can be used to pump water via line 219 to a second reservoir 230 from the first reservoir 220. The ozone generator 236 delivers ozone via line 237 to the second reservoir 230. The ozone injector can provide ozone on a timed basis form between 5 to 15 minutes. The ozone bubbles facilitate mixing in second reservoir 230 as they circulate around platform 232. A platform 232 is provided to facilitate circulation in the second reservoir 230. A sensor 245 detects the water level in the second reservoir 230.

In one embodiment, sensor 245 is a top reservoir float that turns the apparatus on the water production mode with the tank is full. The sensor 245 can also bottom tank float that controls power to the thermostat 259 so that the thermostat 259 can call for chilling to chill coil unless the coil is covered with water. Line 239 drains water from reservoir 230 using pump 238. The water in the reservoir 230 can be further sanitized by a variety of methods including UVC, ultrasound, and ozone.

The water is manually dispensed on an on-demand basis when a control circuit is activated, the water is pumped from storage reservoir 220 through the purification unit 228 at least once, and then out dispenser 240.

In the alternative embodiment, a heating coil 241 can be used to heat the water for delivery. Alternatively, line 229 can be wrapped with a tube containing chilled water from suction line (not shown), high-pressure line (not shown) of the operating compressor 246 to cool the dispensed water or in the alternatively a line can be run close to the evaporating coil 210 to cool the water.

Now referring to FIG. 9, a purification module 299 is shown. The purification module 299 is a includes a the storage reservoir 230, pump device 238, ozonator 236, and water purification unit 228 and fluid lines are contained in a purification module 299 as shown in FIG. 9. Purification module 299 also includes: a pump 238 to move water thorough a purification unit 228. The water purification unit 228 can include an in-line UVC element 272, sedimentation filter (5 mm to 10 mm) 274 carbon block 276 and a second carbon block filter 278. The purification unit 228 can include an active carbon filter to remove organic chemicals, and alternatively a dust filter. More than one purification module 299 can be fluidly linked in series.

The apparatus 201 is controlled by a computer controller based on a sensor reading of temperature or relative humidity settings. Alternatively, the apparatus 201 cans be controlled by water level in reservoir 220 or reservoir 230. When the water level sensor 216 or 245 detects the water level, the apparatus 201 stops producing water.

A large commercial unit can produce 100-3200 gallons of potable water. The potable water produced according with apparatus 201 can be used to fill water bottles. In one embodiment, the water bottles are made of a biodegradable material, such as Oxo Biodegradable (OBD) plastic. OBD is polyolefin plastic to which has been added very small (catalytic) amounts of metal salts. The water bottles can also be recyclable, such as bottles, made with PET.

Now referring to FIGS. 10 and 11, a system is shown wherein the apparatus 201 can be connected in-part to a structure's forced-air distribution system. Thus, the same motor, blower, and ductwork used for heating are used to distribute cool air from the air conditioning system. When a central air conditioner is operating, hot air inside the structure flows to the furnace through the return-air duct 270. The hot air is moved by the blower across the cooled evaporator coil 210 in the plenum and is then delivered through ducts to cool the structure. The evaporator coil 210 used in air-conditioning apparatus, such as a furnace, air handling units, heat pumps and package air conditioners, extracts moisture from the air which flows across the evaporator coil of the evaporator device 210. The moisture extracted creates a condensate on the exterior of the coil 210 which drips into a drain pan 212. If the thermostat 253 shows the desired temperature is reached, the housing 202 includes shutter 275 which can direct cooled air to conduit back to the condensing coil 213.

For example, a conduit system 280 provides conditioned air to the structure 290 wherein the conduit 280 includes a shutter 275 configured to actuate in the closed position, if the temperature of the structure has not achieved a set temperature and configured to actuate in the open position (i.e. pivots 90 degrees to block the conduit) if the temperature has achieved a set temperature.

Similarly, if the relative humidity sensor 282 shows that the relative humidity has dropped below a predetermined point, shutter 288 opens (pivots 45 degrees) to allow entry of moisture rich ambient air. A conduit 270 includes a shutter 288 configured to actuate in the closed position, if the relative humidity sensor 282 in the structure 290 such as a dwelling is above a set number and configured to actuate in the open position if the relative humidity is below a set number. In this embodiment, the air purification mean can be a HEPA filter 206 fixed in the duct 270 or attached to housing 202. In an alternate embodiment, an indoor air purifier 247) is attached to the centralized HVAC system to reduce bacteria and improve air quality. In an alternative embodiment the filter is electrostatic.

Now referring to FIGS. 12 A, B and C an apparatus 301 includes a condensing coil (hot-coil) 313 and evaporating coil (cool-coil) 310 and storage tank 320. The condensing coil 313 is located outside of the structure and is connected to the at least one housing 302 via a flexible refrigerant hose 315. Housing 302, including the evaporating coil 310, is fixedly mounted to either a wall 325 or window 336. This unit is the evaporating unit 311. This housing 302 includes air intake inlet to intake ambient air 335. This opening 335 is a plurality of openings, such as holes, louvers or perforations. The opening 335 allow ambient air to enter the apparatus 301. A “HEPA” filter 306 is attached to evaporating unit 311. Filter 306 allows the ambient air to flow through to the apparatus 301. The air outlet opening 307 is on the bottom of the housing 302. The storage tank 320 is attached to a purification unit 327 that can include a pump 321, an in-line ozone element, string-wound sedimentation filter, carbon block, a second carbon block, and a UVC element. The purification unit 327 can include an active carbon filter to remove organic chemicals, and alternatively a dust filter. Cool air exits the apparatus 302 via vent 331 when fan 308 is activated.

The condensing coil 313 is included in a housing 309 and is fixedly located outside of structure 312. This is the condenser unit 314. Flexible refrigerant hoses 315 and releasable couplings 317 are provided for connecting the evaporator unit 311 with the condenser unit 314. Now referring to FIG. 12C evaporating units 311 are positioned in at least at one room of the structure and are connected via flexible refrigerant hoses 315 and releasable couplings 317 to the condenser unit 314

Now referring to FIG. 13, a large apparatus of 20 or more tons is shown. The 20 ton unit will produce approximately 350 Gallons @ 1.39 KWH/Gal, at @70% humidity at 85 degrees F. The unit included air filter 206 that substantially cover air inlet 205. A first evaporating coil (cool-coil) 210, and a plurality of compressors 246 and a second evaporating coil (cool-coil) 287 is positioned to condense water into a reservoir 220. The water is filtered though water purification unit 228 and then dispensed.

Now referring to FIG. 14, a schematic of the control system 400 for apparatus to produce potable water is shown. The printed circuit board 401 (PCB) contains the electronics that power, monitor and control the system. Connections to the PCB 401 are required to interface it to the elements of the equipment and to the outside environment, including electrical power sources (not shown). The connections are made by means of different types of connectors that allow wires to be attached and/or detached to/from the PCB 401 to various elements of the apparatus 201. These elements that are controlled by the PCB 401 will be discussed. The PCB 401 includes a display circuit 451 which has a digital, alphanumeric readout in housing 202 on the front panel of the apparatus 201. The PCB 401 includes an ozone gas generator control 450 in ozonator 226. The PCB 401 also includes control circuit 450 for ozone line 227.

PCB 401 is connected to the relative humidity sensor 403, ambient temperature sensor 404 evaporator temperature sensor 405 cold water thermostat sensor 406, level sensor for float 3 407, level sensor for float no. 2 408, level sensor for float no. 1, 409, emergency cut-off switch 410, line neutral 411, lead 412 line hot lead 413, spare 414, low evaporator fan speed 415, medium evaporator fan speed 416, high evaporator fan speed 417, line hot lead 418, refrigeration compressor 419, sleep control 420, 24 VAC transformer 421, two way solenoid valve 258 and control circuit 422, two way solenoid valve 257 and control circuit 423, hot gas bypass valve control 424, water pump 238 and control circuit 425, dispenser 240 and dispensing valve control 426, 24 VAC 3-way water solenoid valve (not shown) and control circuit 427 and a plurality of GFI plugs (not shown).

While the present invention is illustrated by description of several embodiments and while the illustrative embodiments are described in detail, it is not the intention of the applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications within the scope of the appended claims will readily appear to those sufficed in the art. The invention in its broader aspects is therefore not limited to the specific details, representative apparatus, and methods, and illustrative examples shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of applicant's general concept. 

1. An apparatus to recover and dispense potable water comprising: a housing including an inlet to intake ambient air, an air purification unit substantially covering said inlet, an evaporator device configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein said device includes an evaporating surface having corrugated shaped fins of between 5-8 fins per cm; a fan positioned to facilitate movement of air across said evaporator device to condense water; a drainage pan positioned to receive water generated by the evaporator device in fluid communication with a reservoir configured to hold condensed water; and at least one water purification unit positioned to purify the condensed water; a fluid line to transport water to a dispensing device to dispense potable water.
 2. The apparatus of claim 1 wherein said drain pan positioned in at least a 5 degree angle from the evaporator device.
 3. The apparatus of claim 1 wherein said evaporating surface has between 6-7 fins per cm.
 4. The apparatus of claim 1 wherein said evaporating surface has a face area from 7 to 35.6 sq/ft.
 5. The apparatus of claim 1 wherein said air purification unit is a HEPA filter.
 6. The apparatus of claim 1 wherein said air purification unit is an electrostatic filter
 7. The apparatus of claim 5 wherein said HEPA filter is between 2.5 to 11 cm in thickness.
 8. The apparatus of claim 1, further comprising a pre-filter in fluid communication with the drainage pan, said pre-filter including a particulate screen for removing particles larger than a predetermined size from water passing through the pre-filter.
 9. The apparatus of claim 1 wherein said fluid line is positioned to chill the water.
 10. The apparatus of claim 1 further said fluid line is positioned to heat the water.
 11. The apparatus of claim 1, wherein said water purification unit is an activated carbon filter, configured to reduce environmental contaminants.
 12. The apparatus of claim 1, wherein said water purification unit is an ultraviolet light treatment filter source, operable to reduce biological contaminants.
 13. The apparatus of claim 1, wherein said water purification unit is an ozonator, configured to purify water by releasing ozone into the water.
 14. The apparatus of claim 1 wherein said reservoir further comprising a platform to facilitate mixing of ozone with the water.
 15. The apparatus of claim 1, wherein the housing includes a plurality of outlet ports substantially covered by shutters.
 16. The apparatus of claim 1 further comprising a condenser coil and a fan positioned to expel cold air from said outlet ports.2
 17. The apparatus of claim 16 wherein said fan is configured to operate at a first speed to provide air-conditioning and a second speed to provide water.
 18. The apparatus of claim 1 wherein said fan is configured to operate at a first speed to provide air-conditioning and a second speed to provide water.
 19. The apparatus of claim 1, wherein said apparatus included an outdoor condensing coil, and at least, one indoor evaporating coil, wherein said outdoor unit and at least one indoor evaporating coil are connected via flexible refrigerant hoses and releasable couplings.
 20. The apparatus of claim 1 further comprising a second reservoir configured to hold water and a second purification unit.
 21. The apparatus of claim 1 further comprising an agitation device positioned to agitate said evaporator device.
 22. The apparatus of claim 1 further comprising a computer operated controller to activate said apparatus based on water level sensor in said first reservoir.
 23. The apparatus of claim 20 further comprising a computer operated controller to activate said apparatus based on water level sensor in said second reservoir.
 24. The apparatus of claim 1 further comprising a second evaporator device.
 25. An apparatus to purify water comprising: a pump to move water thorough said apparatus, a water reservoir positioned to receive unpurified water, an ozonator connected to said reservoir to provide ozone via a dispenser to said reservoir; at least one water purification unit positioned downstream from said water reservoir, including an in-line UVC element, sedimentation filter, and carbon block filter.
 26. The apparatus of claim 25 further comprising a platform positioned in said reservoir to facilitate mixing.
 27. The apparatus of claim 26 wherein said ozone dispenser is substantially near the side of the storage reservoir to facilitate mixing.
 28. The apparatus of claim 25 further comprising as dust filter positioned to remove dust.
 29. A system to provide air-conditioning to a structure and recover and dispense potable water comprising: at least one housing including an inlet to intake ambient air, an air purification unit substantially covering said inlet, an evaporator device configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein said device includes an evaporating surface having corrugated shaped fins of between 5-8 fins per cm, wherein said evaporator device is in fluid communication with a condensing coil; a fan positioned to facilitate movement of air across said evaporator device to condense water; at least one reservoir configured to hold condensed water; and at least one water purification unit positioned to purify the condensed water; and a dispensing device to dispense potable water, and a fan positioned to expel cold air from outlet ports, wherein at least one housing is attached to a dwelling.
 30. The system of claim 29 further comprising: a conduit system to provide conditioned air to said dwelling, wherein said conduit includes a shutter configured to actuate in an open or closed position based on a sensor reading.
 31. The system of claim 29 wherein said condensing coil is located outside of said dwelling and is connected to said at least one housing via a flexible refrigerant hose.
 32. The system of claim 28 wherein said at least one housing is located in different rooms of the dwelling to provide cool air in each room.
 33. The system of claim 29 wherein said condensing coil is located inside said housing.
 34. A method to recover potable water and cool air comprising: providing an apparatus comprising: a housing including an inlet to intake ambient air, an air purification unit substantially covering said inlet, an evaporator device configured to extract water vapor from ambient air and condense the water vapor into liquid water, wherein said device includes an evaporation surface having corrugated shaped fins of between 5-8 fins per cm; a fan positioned to facilitate movement of air across said evaporator device to condense water; a reservoir configured to hold condensed water; and at least one water purification unit positioned to purify the condensed water; and a dispensing device to dispense potable water and air-conditioning coil and a fan positioned to expel cold air from said outlet ports; and operating said fan at one speed to facilitate the extraction of water from ambient air and at a second speed to expel cold air from a plurality of outlet ports in said housing, wherein about 26.5 liters of potable water is produced in 18 hours of operation.
 35. The method of claim 34 further comprising the step of adding the potable water to biodegradable bottles.
 36. The method of claim 34 further comprising the step of adding the potable water to recyclable bottles. 